my-emacs-d/elpa/xpm-1.0.3/xpm.el

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2016-09-26 17:37:47 +00:00
;;; xpm.el --- edit XPM images -*- lexical-binding: t -*-
;; Copyright (C) 2014 Free Software Foundation, Inc.
;; Author: Thien-Thi Nguyen <ttn@gnu.org>
;; Maintainer: Thien-Thi Nguyen <ttn@gnu.org>
;; Version: 1.0.3
;; Keywords: multimedia, xpm
;; URL: http://www.gnuvola.org/software/xpm/
;; This program is free software; you can redistribute it and/or modify
;; it under the terms of the GNU General Public License as published by
;; the Free Software Foundation, either version 3 of the License, or
;; (at your option) any later version.
;; This program is distributed in the hope that it will be useful,
;; but WITHOUT ANY WARRANTY; without even the implied warranty of
;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
;; GNU General Public License for more details.
;; You should have received a copy of the GNU General Public License
;; along with this program. If not, see <http://www.gnu.org/licenses/>.
;;; Commentary:
;; This package makes editing XPM images easy (and maybe fun).
;; Editing is done directly on the (textual) image format,
;; for maximal cohesion w/ the Emacs Way.
;;
;; Coordinates have the form (X . Y), with X from 0 to (width-1),
;; and Y from 0 to (height-1), inclusive, in the 4th quadrant;
;; i.e., X grows left to right, Y top to bottom, origin top-left.
;;
;; (0,0) … (width-1,0)
;; ⋮ ⋮
;; (0,height-1) … (width-1,height-1)
;;
;; In xpm.el (et al), "px" stands for "pixel", a non-empty string
;; in the external representation of the image. The px length is
;; the image's "cpp" (characters per pixel). The "palette" is a
;; set of associations between a px and its "color", which is an
;; alist with symbolic TYPE and and string CVALUE. TYPE is one of:
;;
;; c -- color (most common)
;; s -- symbolic
;; g -- grayscale
;; g4 -- four-level grayscale
;; m -- monochrome
;;
;; and CVALUE is a string, e.g., "blue" or "#0000FF". Two images
;; are "congruent" if their width, height and cpp are identical.
;;
;; This package was originally conceived for non-interactive use,
;; so its design is spartan at the core. However, we plan to add
;; a XPM mode in a future release; monitor the homepage for updates.
;;
;; For now, the features (w/ correspondingly-named files) are:
;; - xpm -- edit XPM images
;; - xpm-m2z -- ellipse/circle w/ fractional center
;;
;; Some things are autoloaded. Which ones? Use the source, Luke!
;; (Alternatively, just ask on help-gnu-emacs (at gnu dot org).)
;;; Code:
(require 'cl-lib)
(autoload 'image-toggle-display "image-mode" t) ; hmm is this TRT?
(defvar xpm-raster-inhibit-continuity-optimization nil
"Non-nil disables a heuristic in `xpm-raster' filling.
Normally, if you pass a well-formed (closed, no edge crossings)
shape to `xpm-raster', then you can ignore this variable.")
(cl-defstruct (xpm--gg ; gathered gleanings
(:type vector) ; no :named so no predicate
(:conc-name xpm--)
(:constructor xpm--make-gg)
(:copier xpm--copy-gg))
(w :read-only t) (h :read-only t) (cpp :read-only t)
pinfo ; (MARKER . HASH-TABLE)
(origin :read-only t)
(y-mult :read-only t)
flags)
(defvar xpm--gg nil
"Various bits for xpm.el (et al) internal use.")
;;;###autoload
(defun xpm-grok (&optional simple)
"Analyze buffer and prepare internal data structures.
When called as a command, display in the echo area a
summary of image dimensions, cpp and palette.
Set buffer-local variable `xpm--gg' and return its value.
Normally, preparation includes making certain parts of the
buffer intangible. Optional arg SIMPLE non-nil inhibits that."
(interactive)
(unless (or
;; easy
(and (boundp 'image-type)
(eq 'xpm image-type))
;; hard
(save-excursion
(goto-char (point-min))
(string= "/* XPM */"
(buffer-substring-no-properties
(point) (line-end-position)))))
(error "Buffer not an XPM image"))
(when (eq 'image-mode major-mode)
(image-toggle-display))
(let ((ht (make-hash-table :test 'equal))
pinfo gg)
(save-excursion
(goto-char (point-min))
(search-forward "{")
(skip-chars-forward "^\"")
(cl-destructuring-bind (w h nc cpp &rest rest)
(read (format "(%s)" (read (current-buffer))))
(ignore rest) ; for now
(forward-line 1)
(setq pinfo (point-marker))
(cl-loop
repeat nc
do (let ((p (1+ (point))))
(puthash (buffer-substring-no-properties
p (+ p cpp))
;; Don't bother w/ CVALUE for now.
t ht)
(forward-line 1)))
(setq pinfo (cons pinfo ht))
(skip-chars-forward "^\"")
(forward-char 1)
(set (make-local-variable 'xpm--gg)
(setq gg (xpm--make-gg
:w w :h h :cpp cpp
:pinfo pinfo
:origin (point-marker)
:y-mult (+ 4 (* cpp w)))))
(unless simple
(let ((mod (buffer-modified-p))
(inhibit-read-only t))
(cl-flet
((suppress (span &rest more)
(let ((p (point)))
(add-text-properties
(- p span) p (cl-list*
'intangible t
more)))))
(suppress 1)
(cl-loop
repeat h
do (progn (forward-char (+ 4 (* w cpp)))
(suppress 4)))
(suppress 2 'display "\n")
(push 'intangible-sides (xpm--flags gg)))
(set-buffer-modified-p mod)))
(when (called-interactively-p 'interactive)
(message "%dx%d, %d cpp, %d colors in palette"
w h cpp (hash-table-count ht)))))
gg))
(defun xpm--gate ()
(or xpm--gg
(xpm-grok)
(error "Sorry, xpm confused")))
(cl-defmacro xpm--w/gg (names from &body body)
(declare (indent 2))
`(let* ((gg ,from)
,@(mapcar (lambda (name)
`(,name (,(intern (format "xpm--%s" name))
gg)))
`,names))
,@body))
;;;###autoload
(defun xpm-generate-buffer (name width height cpp palette)
"Return a new buffer in XPM image format.
In this buffer, undo is disabled (see `buffer-enable-undo').
NAME is the buffer and XPM name. For best interoperation
with other programs, NAME should be a valid C identifier.
WIDTH, HEIGHT and CPP are integers that specify the image
width, height and characters/pixel, respectively.
PALETTE is an alist ((PX . COLOR) ...), where PX is either
a character or string of length CPP, and COLOR is a string.
If COLOR includes a space, it is included directly,
otherwise it is automatically prefixed with \"c \".
For example, to produce palette fragment:
\"X c blue\",
\"Y s border c green\",
you can specify PALETTE as:
((?X . \"blue\")
(?Y . \"s border c green\"))
This example presumes CPP is 1."
(let ((buf (generate-new-buffer name)))
(with-current-buffer buf
(buffer-disable-undo)
(cl-flet
((yep (s &rest args)
(insert (apply 'format s args) "\n")))
(yep "/* XPM */")
(yep "static char * %s[] = {" name)
(yep "\"%d %d %d %d\"," width height (length palette) cpp)
(cl-loop
for (px . color) in palette
do (yep "\"%s %s\","
(if (characterp px)
(string px)
px)
(if (string-match " " color)
color
(concat "c " color))))
(cl-loop
with s = (format "%S,\n" (make-string (* cpp width) 32))
repeat height
do (insert s))
(delete-char -2)
(yep "};")
(xpm-grok t)))
buf))
(defun xpm-put-points (px x y)
"Place PX at coordinate(s) (X,Y).
If both X and Y are vectors of length N, then place N points
using the pairwise vector elements. If one of X or Y is a vector
of length N and the other component is an integer, then pair the
vector elements with the integer component and place N points.
If one of X or Y is a pair (LOW . HIGH), take it to be equivalent
to specfiying a vector [LOW ... HIGH]. For example, (3 . 8) is
equivalent to [3 4 5 6 7 8]. If one component is a pair, the
other must be an integer -- the case where both X and Y are pairs
is not supported.
Silently ignore out-of-range coordinates."
(xpm--w/gg (w h cpp origin y-mult) (xpm--gate)
(when (and (stringp px) (= 1 cpp))
(setq px (aref px 0)))
(cl-flet*
((out (col row)
(or (> 0 col) (<= w col)
(> 0 row) (<= h row)))
(pos (col row)
(goto-char (+ origin (* cpp col) (* y-mult row))))
(jam (col row len)
(pos col row)
(insert-char px len)
(delete-char len))
(rep (col row len)
(pos col row)
(if (= 1 cpp)
(insert-char px len)
(cl-loop
repeat len
do (insert px)))
(delete-char (* cpp len)))
(zow (col row)
(unless (out col row)
(rep col row 1))))
(pcase (cons (type-of x) (type-of y))
(`(cons . integer) (let* ((beg (max 0 (car x)))
(end (min (1- w) (cdr x)))
(len (- end beg -1)))
(unless (or (> 1 len)
(out beg y))
(if (< 1 cpp)
;; general
(rep beg y len)
;; fast(er) path
(when (stringp px)
(setq px (aref px 0)))
(jam beg y len)))))
(`(integer . cons) (cl-loop
for two from (car y) to (cdr y)
do (zow x two)))
(`(vector . integer) (cl-loop
for one across x
do (zow one y)))
(`(integer . vector) (cl-loop
for two across y
do (zow x two)))
(`(vector . vector) (cl-loop
for one across x
for two across y
do (zow one two)))
(`(integer . integer) (zow x y))
(_ (error "Bad coordinates: X %S, Y %S"
x y))))))
(defun xpm-raster (form edge &optional fill)
"Rasterize FORM with EDGE pixel (character or string).
FORM is a list of coordinates that comprise a closed shape.
Optional arg FILL specifies a fill pixel, or t to fill with EDGE.
If FORM is not closed or has inopportune vertical-facing
concavities, filling might give bad results. For those cases,
see variable `xpm-raster-inhibit-continuity-optimization'."
(when (eq t fill)
(setq fill edge))
(xpm--w/gg (h) (xpm--gate)
(let* ((v (make-vector h nil))
(x-min (caar form)) ; (maybe) todo: xpm--bb
(x-max x-min)
(y-min (cdar form))
(y-max y-min)
(use-in-map (not xpm-raster-inhibit-continuity-optimization))
;; These are bool-vectors to keep track of both internal
;; (filled and its "next" (double-buffering)) and external
;; state, on a line-by-line basis.
int nin
ext)
(cl-loop
for (x . y) in form
do (setq x-min (min x-min x)
x-max (max x-max x)
y-min (min y-min y)
y-max (max y-max y))
unless (or (> 0 y)
(<= h y))
do (push x (aref v y)))
(cl-flet
((span (lo hi)
(- hi lo -1))
(norm (n)
(- n x-min))
(rset (bv start len value)
(cl-loop
for i from start repeat len
do (aset bv i value)))
(scan (bv start len yes no)
(cl-loop
for i from start repeat len
when (aref bv i)
return yes
finally return no)))
(let ((len (span x-min x-max)))
(setq int (make-bool-vector len nil)
nin (make-bool-vector len nil)
ext (make-bool-vector len t)))
(cl-loop
with (ls
in-map-ok
in-map)
for y from (1- y-min) to y-max
when (setq ls (and (< -1 y)
(> h y)
(sort (aref v y) '>)))
do (cl-loop
with acc = (list (car ls))
for maybe in (cdr ls)
do (let* ((was (car acc))
(already (consp was)))
(cond ((/= (1- (if already
(car was)
was))
maybe)
(push maybe acc))
(already
(setcar was maybe))
(t
(setcar acc (cons maybe was)))))
finally do
(when fill
(let ((was (length in-map))
(now (length acc)))
(unless (setq in-map-ok
(and (= was now)
;; heuristic: Avoid being fooled
;; by simulataneous crossings.
(cl-evenp was)))
(setq in-map (make-bool-vector now nil)))))
finally do
(cl-loop
with (x rangep beg nx end len nb in)
for gap from 0
while acc
do (setq x (pop acc))
do (xpm-put-points edge x y)
do (when fill
(setq rangep (consp x))
(when (zerop gap)
(rset ext 0 (norm (if rangep
(car x)
x))
t))
(if rangep
(cl-destructuring-bind (b . e) x
(rset ext (norm b) (span b e) nil))
(aset ext (norm x) nil))
(when acc
(setq beg (1+ (if rangep
(cdr x)
x))
nx (car acc)
end (1- (if (consp nx)
(car nx)
nx))
len (span beg end)
nb (norm beg)
in (cond ((and use-in-map in-map-ok)
(aref in-map gap))
(in (scan int nb len t nil))
(t (scan ext nb len nil t))))
(unless in-map-ok
(aset in-map gap in))
(if (not in)
(rset ext nb len t)
(rset nin nb len t)
(xpm-put-points fill (cons beg end) y))))
finally do (when fill
(cl-rotatef int nin)
(fillarray nin nil)))))))))
(defun xpm-as-xpm (&rest props)
"Return the XPM image (via `create-image') of the buffer.
PROPS are additional image properties to place on
the new XPM. See info node `(elisp) XPM Images'."
(apply 'create-image (buffer-substring-no-properties
(point-min) (point-max))
'xpm t props))
(defun xpm-finish (&rest props)
"Like `xpm-as-xpm', but also kill the buffer afterwards."
(prog1 (apply 'xpm-as-xpm props)
(kill-buffer nil)))
(provide 'xpm)
;;; xpm.el ends here